[PDF][PDF] Bidirectional anticipation of future osmotic challenges by vasopressin neurons

Y Mandelblat-Cerf, A Kim, CR Burgess, S Subramanian… - Neuron, 2017 - cell.com
Y Mandelblat-Cerf, A Kim, CR Burgess, S Subramanian, BA Tannous, BB Lowell…
Neuron, 2017cell.com
Ingestion of water and food are major hypo-and hyperosmotic challenges. To protect the
body from osmotic stress, posterior pituitary-projecting, vasopressin-secreting neurons (VP
pp neurons) counter osmotic perturbations by altering their release of vasopressin, which
controls renal water excretion. Vasopressin levels begin to fall within minutes of water
consumption, even prior to changes in blood osmolality. To ascertain the precise temporal
dynamics by which water or food ingestion affect VP pp neuron activity, we directly recorded …
Summary
Ingestion of water and food are major hypo- and hyperosmotic challenges. To protect the body from osmotic stress, posterior pituitary-projecting, vasopressin-secreting neurons (VPpp neurons) counter osmotic perturbations by altering their release of vasopressin, which controls renal water excretion. Vasopressin levels begin to fall within minutes of water consumption, even prior to changes in blood osmolality. To ascertain the precise temporal dynamics by which water or food ingestion affect VPpp neuron activity, we directly recorded the spiking and calcium activity of genetically defined VPpp neurons. In states of elevated osmolality, water availability rapidly decreased VPpp neuron activity within seconds, beginning prior to water ingestion, upon presentation of water-predicting cues. In contrast, food availability following food restriction rapidly increased VPpp neuron activity within seconds, but only following feeding onset. These rapid and distinct changes in activity during drinking and feeding suggest diverse neural mechanisms underlying anticipatory regulation of VPpp neurons.
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